The transcriptional repressor CDP (Cutl1) is essential for epithelial cell differentiation of the lung and the hair follicle.

The mammalian Cutl1 gene codes for the CCAAT displacement protein (CDP), which has been implicated as a transcriptional repressor in diverse processes such as terminal differentiation, cell cycle progression, and the control of nuclear matrix attachment regions. To investigate the in vivo function of Cutl1, we have replaced the C-terminal Cut repeat 3 and homeodomain exons with an in-frame lacZ gene by targeted mutagenesis in the mouse. The CDP-lacZ fusion protein is retained in the cytoplasm and fails to repress gene transcription, indicating that the Cutl1(lacZ) allele corresponds to a null mutation. Cutl1 mutant mice on inbred genetic backgrounds are born at Mendelian frequency, but die shortly after birth because of retarded differentiation of the lung epithelia, which indicates an essential role of CDP in lung maturation. A less pronounced delay in lung development allows Cutl1 mutant mice on an outbred background to survive beyond birth. These mice are growth-retarded and develop an abnormal pelage because of disrupted hair follicle morphogenesis. The inner root sheath (IRS) is reduced, and the transcription of Sonic hedgehog and IRS-specific genes is deregulated in Cutl1 mutant hair follicles, consistent with the specific expression of Cutl1 in the progenitors and cell lineages of the IRS. These data implicate CDP in cell-lineage specification during hair follicle morphogenesis, which resembles the role of the related Cut protein in specifying cell fates during Drosophila development.

Pax5/BSAP maintains the identity of B cells in late B lymphopoiesis.

The B lineage commitment factor Pax5 (BSAP) is expressed throughout B cell development. To investigate its late function, we generated a mouse strain carrying a floxed Pax5 allele that was conditionally inactivated by CD19-cre or Mx-cre expression. Pax5 deletion resulted in the preferential loss of mature B cells, inefficient lymphoblast formation, and reduced serum IgG levels. Mature B cells radically changed their gene expression pattern in response to Pax5 inactivation. Most B cell antigens were downregulated on the cell surface, and the transcription of B cell-specific genes was decreased, whereas the expression of non-B lymphoid genes was activated in Pax5-deficient B cells. These data demonstrate that Pax5 is essential for maintaining the identity and function of B cells during late B lymphopoiesis.

Pax5 determines the identity of B cells from the beginning to the end of B-lymphopoiesis.

Despite being one of the most intensively studied cell types, the molecular basis of B cell specification is largely unknown. The Pax5 gene encoding the transcription factor BSAP is required for progression of B-lymphopoiesis beyond the pro-B cell stage. Pax5-deficient pro-B cells are, however, not yet committed to the B-lymphoid lineage, but instead have a broad lymphomyeloid developmental potential. Pax5 appears to mediate B-lineage commitment by repressing the transcription of non-B-lymphoid genes and by simultaneously activating the expression of B-lineage-specific genes. Pax5 thus functions both as a transcriptional repressor and activator, depending on its interactions with corepressors of the Groucho protein family or with positive regulators such as the TATA-binding protein. Once committed to the B-lineage, B cells require Pax5 function to maintain their B-lymphoid identity throughout B cell development.

IL-8 derivatives with a reduced potential to form homodimers are fully active in vitro and in vivo.

Interleukin 8 (IL-8) is a member of the CXC subfamily of chemokines which attracts and activates preferentially neutrophilic granulocytes. At nanomolar concentrations monomeric and dimeric forms of the molecule are in equilibrium, with the monomer being the prevalent form. Five amino acids from position 23 to 29 of the 72-amino acid IL-8 sequence form the dimer interface, with Leu25 and Val27 being highly conserved among the CXC chemokines. To investigate the contribution of these amino acids to the dimerization of IL-8, we produced in escherichia coli IL-8 derivatives with phenylalanine substitutions at position 25 or 27, or both 25 and 27. All three recombinant proteins were characterized by a significantly impaired potential to form dimers in solution as seen in chemical crosslinking experiments. IL-8 Val27 also could not be crosslinked as a dimer on its receptors. Receptor affinities and in vitro chemotactic activities, however, were not significantly different between wild-type and IL-8 with single mutations. The dimerization deficient IL-8 analogue had also full inflammatory activity in vivo. Thus, the monomer is the biologically active form of IL-8.

Structure and activity of a chimeric interleukin-8-melanoma-growth-stimulatory-activity protein.

A 72-amino-acid chimeric protein, Chi1, was constructed from the N-terminal part of interleukin 8, IL-8-(1-53), and the C-terminal part of melanoma growth stimulatory activity, MGSA-(54-72). Chi1 protein showed receptor-binding specificity and biological activity similar, but not identical to IL-8 and decidedly different from MGSA. The structure of Chi1 was determined in solution by two-dimensional NMR and molecular-dynamics calculations. The structure resembled the structures of MGSA and IL-8 closely, containing a triple-stranded beta-sheet in the IL-8 part and an amphipathic alpha-helix in the MGSA part. Chi1 formed dimers at millimolar concentrations via the first strand from the N-terminus, analogous to IL-8 and MGSA. In contrast to the latter molecules, however, the alpha-helix of Chi1 did not pack against the beta-sheet part, but was an independent structural element. This structural difference could be explained mainly by the modulation of hydrophobic interactions between the helix and the rest of the protein in Chi1 as compared to IL-8 and MGSA. It is concluded that tight helix packing is not required for receptor binding and biological activity of Chi1.